I. Introduction

Over the past few decades, various teleoperation systems have been developed for remote robot control. They have been used for a variety of tasks, such as operating robotic arms or mechanical systems in remote areas (e.g., for controlling surgical robots, and handling harmful or toxic materials like in nuclear reactors). A teleoperation system consists of a master system for manipulation by an operator and a slave robot remotely controlled by the master movements. In a bilateral teleoperation system, the master and the slave are connected through communication networks that transfer various information, including the master and slave positions, the interaction forces between master system and operator and between slave system and environment, and visual data. Several transparency and stability studies have been recently conducted to understand how to obtain haptic feedback [1]–[4]. In teleoperation, the operator needs to effectively manipulate the slave robot through tactile and kinesthetic feedback; however, visual feedback is still one of the most important factors when a person manipulates a robot remotely. Since a human being obtains more than 90% of information through vision [5], trouble may arise if the operator cannot rely on accurate visual data.